A probe thermometer is a thermometer that has a pointy metal stem that can be inserted into food. Using a probe thermometer helps to make sure the proper internal food temperatures are reached and maintained so you don’t risk being sick with a food-borne illness.
Color is Not a Reliable Indicator
Many food handlers believe that visible indicators, such as color changes, can be used to determine if foods are cooked to a point where pathogens are killed. However, recent research has shown that color and texture indicators are unreliable. For example, ground beef may turn brown before it reaches a temperature where pathogens are destroyed. A consumer preparing hamburger patties and using the brown color as an indicator of “doneness” is taking a chance that pathogenic microorganisms may survive. A hamburger cooked to 160 °F as measured with a meat thermometer, regardless of color, is safe.
The temperature at which different pathogenic microorganisms are destroyed varies, as does the “doneness” temperature for different meat and poultry. A consumer looking for a visual sign of “doneness” might continue cooking it until it is overcooked and dry. However, a consumer using a food thermometer to check for “doneness” can feel assured the food has reached a safe temperature and is not overcooked. Cook all raw beef, pork, lamb and veal steaks, chops, and roasts to a minimum internal temperature of 145°F as measured with a food thermometer before removing meat from the heat source. For safety and quality, allow meat to rest for at least three minutes before carving or consuming. For reasons of personal preference, consumers may choose to cook meat to higher temperatures.
Cook all poultry to a safe minimum internal temperature of 165 °F as measured with a food thermometer. For reasons of personal preference, consumers may choose to cook meat to higher temperatures.
A food thermometer should also be used to ensure that cooked food is held at safe temperatures until served. Cold foods should be held at 40 °F or below. Hot food should be kept hot at 140 °F or above.
Food thermometers come in several types and styles, and vary in level of technology and price.
Of all food thermometers, thermocouple thermometers reach and display the final temperature the fastest – within 2 to 5 seconds. The temperature is indicated on a digital display.
A thermocouple measures temperature at the junction of two fine wires located in the tip of the probe. Thermocouples used in scientific laboratories have very thin probes, similar to hypodermic needles, while others may have a thickness of 1/16 of an inch.
Since thermocouple thermometers respond so rapidly, the temperature can be quickly checked in a number of locations to ensure that the food is safely cooked. This is especially useful for cooking large foods, such as roasts or turkeys, when checking the temperature in more than one place is advised. The thin probe of the thermocouple also enables it to accurately read the temperature of thin foods such as hamburger patties, pork chops, and chicken breasts.
Thermocouples are not designed to remain in the food while its cooking. They should be used near the end of the estimated cooking time to check for final cooking temperatures. To prevent overcooking, check the temperature before the food is expected to finish cooking.
Thermocouples can be calibrated for accuracy.
Thermistor-style food thermometers use a resistor (a ceramic semiconductor bonded in the tip with temperature-sensitive epoxy) to measure temperature. The thickness of the probe is approximately 1/8 of an inch and takes roughly 10 seconds to register the temperature on the digital display. Since the semiconductor is in the tip, thermistors can measure temperature in thin foods, as well as thick foods. Because the center of a food is usually cooler than the outer surface, place the tip in the center of the thickest part of the food.
Thermistors are not designed to remain in the food while its cooking. They should be used near the end of the estimated cooking time to check for final cooking temperatures. To prevent overcooking, check the temperature before the food is expected to finish cooking.
Not all thermistors can be calibrated. Check the manufacturers instructions.
This food thermometer allows the cook to check the temperature of food in the oven without opening the oven door. A base unit with a digital screen is attached to a thermistor-type food thermometer probe by a long metal cord. The probe is inserted into the food, and the cord extends from the oven to the base unit. The base can be placed on the counter or attached to the stovetop or oven door by a magnet. The thermometer is programmed for the desired temperature and beeps when it is reached. While designed for use in ovens, these thermometers can also be used to check foods cooking on the stove. Oven cord thermometers cannot be calibrated.
This utensil combines a cooking fork with a food thermometer. A temperature-sensing device is embedded in one of the tines of the fork. There are several different brands and styles of thermometer forks on the market; some using thermocouples and some using thermistors. The food temperature is indicated on a digital display or by indicator lights on the handle within 2 to 10 seconds (depending on the type). These lights will tell if the food has reached rare, medium, well done, etc. Particularly useful for grilling, the thermometer fork will accurately measure the internal temperature of even the thinnest foods. The thermometer fork should be used to check the temperature of a food towards the end of the estimated cooking time. Thermometer forks are not designed to remain in a food while in the oven or on the grill. Thermometer forks cannot be calibrated.
These thermometers contain a coil in the probe made of two different metals that are bonded together. The two metals have different rates of expansion. The coil, which is connected to the temperature indicator, expands when heated. This food thermometer senses temperature from its tip and up the stem for 2 to 2 1/2 inches. The resulting temperature is an average of the temperatures along the sensing area. These food thermometers have a dial display and are available as “oven-safe” and “instant-read.”
This food thermometer is designed to remain in the food while it is cooking in the oven, and is generally used for large items such as a roast or turkey. This food thermometer is convenient because it constantly shows the temperature of the food while it is cooking. However, if not left in the food while cooking, they can take as long as 1 to 2 minutes to register the correct temperature.
The bimetal food thermometer can accurately measure the temperature of relatively thick foods (such as beef roasts) or deep foods (foods in a stockpot). Because the temperature-sensing coil on the stem is between 2 to 2 1/2 inches long and the stem is relatively thick, it is not appropriate to measure the temperature of any food less than 3 inches thick.
There is concern that because heat conducts along the stems metal surface faster than through the food, the area of the food in contact with the thermometer tip will be hotter than the area a short distance to the side (the “potato nail effect”). To remedy this, the temperature should be taken in a second, and even third area, to verify the temperature of the food. Each time the thermometer is inserted into the food, let the thermometer equilibrate (come to temperature) at least 1 minute before reading the temperature.
Some models can be calibrated. Check the manufacturers instructions.
This food thermometer quickly measures the temperature of a food in about 15 to 20 seconds. It is not designed to remain in the food while it is cooking in the oven, but should be used near the end of the estimated cooking time to check for final cooking temperatures. To prevent overcooking, check the temperature before the food is expected to finish cooking.
For accurate temperature measurement, the probe of the bimetallic-coil thermometer must be inserted the full length of the sensing area (usually 2 to 3 inches). If measuring the temperature of a thin food, such as a hamburger patty or boneless chicken breast, the probe should be inserted through the side of the food so that the entire sensing area is positioned through the center of the food. Some models can be calibrated. Check the manufacturers instructions.
One of the most recent developments in the retail food market is the emergence of disposable temperature indicators. Several brands are available, and all make quick work of determining if a food has reached its final temperature. These temperature sensors are designed for specific temperature ranges, for example, 160-170 °F. It is important that the sensors be used only with foods for which they are intended. Read the package directions to ensure that the temperature the sensor will reach is consistent with the safe temperatures listed in this publication.
The sensors are made from special temperature-sensitive materials. The sensor is inserted into a food. When the food reaches the safe temperature, the sensor changes color. They are designed to be used only once. However, if the desired temperature has not been reached, they can be reinserted until the temperature is reached. These sensors cannot be left in a food while it is cooking. They should be used near the end of the estimated cooking time. To prevent overcooking, check the temperature before the food is expected to finish cooking.
Disposable temperature indicators are made from materials approved by the FDA for contact with food.
Commonly used in turkeys and roasting chickens since 1965, the “pop-up” style disposable cooking device is constructed from a food grade nylon. The inside contains a stainless steel spring and organic firing material. The organic firing material is specifically designed to dissolve at specific predetermined temperatures. Once the firing material dissolves, the stainless steel spring releases the stem, allowing it to “pop up.” This indicates that the food has reached the correct final temperature for safety and doneness. Pop-up style disposable cooking devices are reliable to within 1 to 2 °F, however, proper placement is important. Checking with a conventional food thermometer is always recommended as an added precaution to properly gauging both safety and doneness.
Also called “spirit-filled” or “liquid in glass” thermometers, these thermometers are the oldest kind of food thermometer used in home kitchens. They have either metal or glass stems. As the internal temperature of the food increases, the colored liquid inside the stem expands and rises to indicate the temperature on a scale. Heat conduction in the metal stems can cause false high readings. They are designed to remain in the food while it is cooking. They should be inserted at least 2 inches deep in the thickest part of the food, and are, therefore, not appropriate for thin foods. Some liquid-filled thermometers can be calibrated by carefully moving the glass stem within the holder.
These thermometers will measure temperatures ranging from 100 to 400 °F. They are used to measure the extra-high temperatures required of candy and jelly making, as well as frying with hot oil.
For safety, it is important to verify the temperature of refrigerators and freezers. Refrigerators should maintain a temperature of 40 °F or below. Frozen food will hold its top quality for the longest possible time when the freezer maintains 0 °F or below. An appliance thermometer can be kept in the refrigerator and freezer to monitor the temperature. This can be critical in the event of a power outage. When the power goes back on, if the refrigerator is 40 °F or below, and the freezer is still colder than 40 °F, the food is safe. These bimetallic-coil thermometers are specially designed to provide accuracy at cold temperatures.
An oven thermometer can be left in the oven to verify that the oven is heating to the desired temperatures. These bimetallic-coil thermometers can measure temperatures from 100 to 600 °F.
Most pathogens are destroyed between 140 and 165 °F. Higher temperatures may be necessary to achieve consumer acceptability and palatability, also known as “doneness.”
These temperatures are recommended for consumer cooking. They are not intended for processing, institutional, or foodservice preparation. Food service professionals should consult their state or local food code.
Call Our Hotline For help with meat, poultry, and egg products, call the toll-free USDA Meat and Poultry Hotline:
It is essential to use a food thermometer when cooking meat, poultry, and egg products to prevent undercooking, verify that food has reached a safe minimum internal temperature, and consequently, prevent foodborne illness.
How to Use a Probe Thermometer Correctly
FAQ
What is a product probe used for?
How do you check food with a probe?
How often should you probe food?
How do I use a digital probe food thermometer?
Using a digital probe food thermometer with your BBQ smoker makes it easy to confirm that your meats are at a safe temperature. Our guide will walk you through the process of using the probe correctly. When you start your smoker, insert your digital meat probe into the deepest part of your cut of meat.
Why do I need a food probe?
Food probes are mainly used to know when dinner is ready! You want the protein to be safely cooked to food standard internal temperatures and similarly you don’t want to overcook the food. Safely monitor your food’s temperature throughout the cooking time to ensure you don’t overcook it.
How do you use a digital meat probe?
When you start your smoker, insert your digital meat probe into the deepest part of your cut of meat. For steaks or a roast, this area is usually in the middle. Poultry is deepest along the depth of the inner thigh. Avoid coming into contact with the bones because it can give you an inaccurate readout on your cooking probe.
What is a probe thermometer?
A probe thermometer is a thermometer that has a pointy metal stem that can be inserted into food. Using a probe thermometer helps to make sure the proper internal food temperatures are reached and maintained so you don’t risk being sick with a food-borne illness.